Demonstration of the conversion pipeline using time-resolved ARPES data stored on Zenodo#
In this example, we pull some time-resolved ARPES data from Zenodo, and load it into the sed package using functions of the mpes package. Then, we run a conversion pipeline on it, containing steps for visualizing the channels, correcting image distortions, calibrating the momentum space, correcting for energy distortions and calibrating the energy axis. Finally, the data are binned in calibrated axes. For performance reasons, best store the data on a locally attached storage (no network drive). This can also be achieved transparently using the included MirrorUtil class.
[1]:
%load_ext autoreload
%autoreload 2
import numpy as np
import matplotlib.pyplot as plt
import sed
from sed.dataset import dataset
%matplotlib widget
Load Data#
[2]:
dataset.get("WSe2") # Put in Path to a storage of at least 20 GByte free space.
data_path = dataset.dir # This is the path to the data
scandir, caldir = dataset.subdirs # scandir contains the data, caldir contains the calibration files
INFO - Not downloading WSe2 data as it already exists at "/home/runner/work/sed/sed/docs/tutorial/datasets/WSe2".
Set 'use_existing' to False if you want to download to a new location.
INFO - Using existing data path for "WSe2": "/home/runner/work/sed/sed/docs/tutorial/datasets/WSe2"
INFO - WSe2 data is already present.
[3]:
# create sed processor using the config file:
sp = sed.SedProcessor(folder=scandir, config="../sed/config/mpes_example_config.yaml", verbose=True)
Configuration loaded from: [/home/runner/work/sed/sed/docs/sed/config/mpes_example_config.yaml]
Default config loaded from: [/home/runner/work/sed/sed/sed/config/default.yaml]
[4]:
# Apply jittering to X, Y, t, ADC columns.
# Columns are defined in the config, or can be provided as list.
sp.add_jitter()
[5]:
# Plot of the count rate through the scan
rate, secs = sp.loader.get_count_rate(range(100))
plt.plot(secs, rate)
[5]:
[<matplotlib.lines.Line2D at 0x7faaf03bf640>]
[6]:
# The time elapsed in the scan
sp.loader.get_elapsed_time()
[6]:
2588.4949999999994
[7]:
# Inspect data in dataframe Columns:
# axes = ['X', 'Y', 't', 'ADC']
# bins = [100, 100, 100, 100]
# ranges = [(0, 1800), (0, 1800), (130000, 140000), (0, 9000)]
# sp.view_event_histogram(dfpid=1, axes=axes, bins=bins, ranges=ranges)
sp.view_event_histogram(dfpid=2)
Distortion correction and Momentum Calibration workflow#
Distortion correction#
1. step:#
Bin and load part of the dataframe in detector coordinates, and choose energy plane where high-symmetry points can well be identified. Either use the interactive tool, or pre-select the range:
[8]:
#sp.bin_and_load_momentum_calibration(df_partitions=20, plane=170)
sp.bin_and_load_momentum_calibration(df_partitions=100, plane=33, width=10, apply=True)
2. Step:#
Next, we select a number of features corresponding to the rotational symmetry of the material, plus the center. These can either be auto-detected (for well-isolated points), or provided as a list (these can be read-off the graph in the cell above). These are then symmetrized according to the rotational symmetry, and a spline-warping correction for the x/y coordinates is calculated, which corrects for any geometric distortions from the perfect n-fold rotational symmetry.
[9]:
#features = np.array([[203.2, 341.96], [299.16, 345.32], [350.25, 243.70], [304.38, 149.88], [199.52, 152.48], [154.28, 242.27], [248.29, 248.62]])
#sp.define_features(features=features, rotation_symmetry=6, include_center=True, apply=True)
# Manual selection: Use a GUI tool to select peaks:
#sp.define_features(rotation_symmetry=6, include_center=True)
# Autodetect: Uses the DAOStarFinder routine to locate maxima.
# Parameters are:
# fwhm: Full-width at half maximum of peaks.
# sigma: Number of standard deviations above the mean value of the image peaks must have.
# sigma_radius: number of standard deviations around a peak that peaks are fitted
sp.define_features(rotation_symmetry=6, auto_detect=True, include_center=True, fwhm=10, sigma=12, sigma_radius=4, apply=True)
3. Step:#
Generate nonlinear correction using splinewarp algorithm. If no landmarks have been defined in previous step, default parameters from the config are used
[10]:
# Option whether a central point shall be fixed in the determination fo the correction
sp.generate_splinewarp(include_center=True)
Calculated thin spline correction based on the following landmarks:
pouter: [[153.40227764 243.05435044]
[199.53400773 152.77902026]
[203.00434045 342.98974816]
[299.87354492 346.19664263]
[305.64711935 150.20810267]
[350.95314894 244.78880006]]
pcent: (249.2274827397449, 249.2560987721979)
Original slice with reference features
Corrected slice with target features
Original slice with target features
Optional (Step 3a):#
Save distortion correction parameters to configuration file in current data folder:
[11]:
# Save generated distortion correction parameters for later reuse
sp.save_splinewarp()
Saved momentum correction parameters to "sed_config.yaml".
4. Step:#
To adjust scaling, position and orientation of the corrected momentum space image, you can apply further affine transformations to the distortion correction field. Here, first a potential scaling is applied, next a translation, and finally a rotation around the center of the image (defined via the config). One can either use an interactive tool, or provide the adjusted values and apply them directly.
[12]:
#sp.pose_adjustment(xtrans=14, ytrans=18, angle=2)
sp.pose_adjustment(xtrans=8, ytrans=7, angle=-4, apply=True)
5. Step:#
Finally, the momentum correction is applied to the dataframe, and corresponding meta data are stored
[13]:
sp.apply_momentum_correction()
Adding corrected X/Y columns to dataframe:
Calculating inverse deformation field, this might take a moment...
Dask DataFrame Structure:
X Y t ADC Xm Ym
npartitions=100
float64 float64 float64 float64 float64 float64
... ... ... ... ... ...
... ... ... ... ... ... ...
... ... ... ... ... ...
... ... ... ... ... ...
Dask Name: apply_dfield, 206 graph layers
Momentum calibration workflow#
1. Step:#
First, the momentum scaling needs to be calibrated. Either, one can provide the coordinates of one point outside the center, and provide its distance to the Brillouin zone center (which is assumed to be located in the center of the image), one can specify two points on the image and their distance (where the 2nd point marks the BZ center),or one can provide absolute k-coordinates of two distinct momentum points.
If no points are provided, an interactive tool is created. Here, left mouse click selects the off-center point (brillouin_zone_centered=True) or toggle-selects the off-center and center point.
[14]:
k_distance = 2/np.sqrt(3)*np.pi/3.28 # k-distance of the K-point in a hexagonal Brillouin zone
#sp.calibrate_momentum_axes(k_distance = k_distance)
point_a = [308, 345]
sp.calibrate_momentum_axes(point_a=point_a, k_distance = k_distance, apply=True)
#point_b = [247, 249]
#sp.calibrate_momentum_axes(point_a=point_a, point_b = point_b, k_coord_a = [.5, 1.1], k_coord_b = [0, 0], equiscale=False)
Optional (Step 1a):#
Save momentum calibration parameters to configuration file in current data folder:
[15]:
# Save generated momentum calibration parameters for later reuse
sp.save_momentum_calibration()
Saved momentum calibration parameters to sed_config.yaml
2. Step:#
Now, the distortion correction and momentum calibration needs to be applied to the dataframe.
[16]:
sp.apply_momentum_calibration()
Adding kx/ky columns to dataframe:
Dask DataFrame Structure:
X Y t ADC Xm Ym kx ky
npartitions=100
float64 float64 float64 float64 float64 float64 float64 float64
... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ...
Dask Name: assign, 216 graph layers
Energy Correction and Calibration workflow#
Energy Correction (optional)#
The purpose of the energy correction is to correct for any momentum-dependent distortion of the energy axis, e.g. from geometric effects in the flight tube, or from space charge
1st step:#
Here, one can select the functional form to be used, and adjust its parameters. The binned data used for the momentum calibration is plotted around the Fermi energy (defined by tof_fermi), and the correction function is plotted ontop. Possible correction functions are: “spherical” (parameter: diameter), “Lorentzian” (parameter: gamma), “Gaussian” (parameter: sigma), and “Lorentzian_asymmetric” (parameters: gamma, amplitude2, gamma2).
One can either use an interactive alignment tool, or provide parameters directly.
[17]:
#sp.adjust_energy_correction(amplitude=2.5, center=(730, 730), gamma=920, tof_fermi = 66200)
sp.adjust_energy_correction(amplitude=2.5, center=(730, 730), gamma=920, tof_fermi = 66200, apply=True)
Optional (Step 1a):#
Save energy correction parameters to configuration file in current data folder:
[18]:
# Save generated energy correction parameters for later reuse
sp.save_energy_correction()
Saved energy correction parameters to sed_config.yaml
2. Step#
After adjustment, the energy correction is directly applied to the TOF axis.
[19]:
sp.apply_energy_correction()
Applying energy correction to dataframe...
Using energy correction parameters generated on 11/11/2024, 19:04:00
Dask DataFrame Structure:
X Y t ADC Xm Ym kx ky tm
npartitions=100
float64 float64 float64 float64 float64 float64 float64 float64 float64
... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ...
Dask Name: assign, 230 graph layers
Energy calibration#
For calibrating the energy axis, a set of data taken at different bias voltages around the value where the measurement was taken is required.
1. Step:#
In a first step, the data are loaded, binned along the TOF dimension, and normalized. The used bias voltages can be either provided, or read from attributes in the source files if present.
[20]:
# Load energy calibration EDCs
energycalfolder = caldir
scans = np.arange(1,12)
voltages = np.arange(12,23,1)
files = [energycalfolder + r'/Scan' + str(num).zfill(3) + '_' + str(num+11) + '.h5' for num in scans]
sp.load_bias_series(data_files=files, normalize=True, biases=voltages, ranges=[(64000, 75000)])
2. Step:#
Next, the same peak or feature needs to be selected in each curve. For this, one needs to define “ranges” for each curve, within which the peak of interest is located. One can either provide these ranges manually, or provide one range for a “reference” curve, and infer the ranges for the other curves using a dynamic time warping algorithm.
[21]:
# Option 1 = specify the ranges containing a common feature (e.g an equivalent peak) for all bias scans
# rg = [(129031.03103103103, 129621.62162162163), (129541.54154154155, 130142.14214214214), (130062.06206206206, 130662.66266266267), (130612.61261261262, 131213.21321321322), (131203.20320320321, 131803.8038038038), (131793.7937937938, 132384.38438438438), (132434.43443443443, 133045.04504504506), (133105.10510510512, 133715.71571571572), (133805.8058058058, 134436.43643643643), (134546.54654654654, 135197.1971971972)]
# sp.find_bias_peaks(ranges=rg, infer_others=False)
# Option 2 = specify the range for one curve and infer the others
# This will open an interactive tool to select the correct ranges for the curves.
# IMPORTANT: Don't choose the range too narrow about a peak, and choose a refid
# somewhere in the middle or towards larger biases!
rg = (66100, 67000)
sp.find_bias_peaks(ranges=rg, ref_id=5, infer_others=True, apply=True)
3. Step:#
Next, the detected peak positions and bias voltages are used to determine the calibration function. This can be either done by fitting the functional form d2/(t-t0)2 via lmfit (“lmfit”), or using a polynomial approximation (“lstsq” or “lsqr”). Here, one can also define a reference id, and a reference energy. Those define the absolute energy position of the feature used for calibration in the “reference” trace, at the bias voltage where the final measurement has been performed. The energy scale can be either “kinetic” (decreasing energy with increasing TOF), or “binding” (increasing energy with increasing TOF).
After calculating the calibration, all traces corrected with the calibration are plotted ontop of each other, the calibration function together with the extracted features is plotted.
[22]:
# use the refid of the bias that the measurement was taken at
# Eref can be used to set the absolute energy (kinetic energy, E-EF) of the feature used for energy calibration (if known)
refid=4
Eref=-0.5
# the lmfit method uses a fit of (d/(t-t0))**2 to determine the energy calibration
# limits and starting values for the fitting parameters can be provided as dictionaries
sp.calibrate_energy_axis(
ref_id=refid,
ref_energy=Eref,
method="lmfit",
energy_scale='kinetic',
d={'value':1.0,'min': .7, 'max':1.2, 'vary':True},
t0={'value':8e-7, 'min': 1e-7, 'max': 1e-6, 'vary':True},
E0={'value': 0., 'min': -100, 'max': 0, 'vary': True},
verbose=True,
)
[[Fit Statistics]]
# fitting method = leastsq
# function evals = 43
# data points = 11
# variables = 3
chi-square = 0.00218781
reduced chi-square = 2.7348e-04
Akaike info crit = -87.7502612
Bayesian info crit = -86.5565754
[[Variables]]
d: 1.09544523 +/- 0.03646409 (3.33%) (init = 1)
t0: 7.6073e-07 +/- 7.5361e-09 (0.99%) (init = 8e-07)
E0: -46.6158341 +/- 0.79487877 (1.71%) (init = 0)
[[Correlations]] (unreported correlations are < 0.100)
C(d, t0) = -0.9997
C(d, E0) = -0.9988
C(t0, E0) = +0.9974
Quality of Calibration:
E/TOF relationship:
Optional (Step 3a):#
Save energy calibration parameters to configuration file in current data folder:
[23]:
# Save generated energy calibration parameters for later reuse
sp.save_energy_calibration()
Saved energy calibration parameters to "sed_config.yaml".
4. Step:#
Finally, the the energy axis is added to the dataframe.
[24]:
sp.append_energy_axis()
Adding energy column to dataframe:
Using energy calibration parameters generated on 11/11/2024, 19:04:09
Dask DataFrame Structure:
X Y t ADC Xm Ym kx ky tm energy
npartitions=100
float64 float64 float64 float64 float64 float64 float64 float64 float64 float64
... ... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ... ...
... ... ... ... ... ... ... ... ... ...
Dask Name: assign, 240 graph layers
4. Delay calibration:#
The delay axis is calculated from the ADC input column based on the provided delay range. ALternatively, the delay scan range can also be extracted from attributes inside a source file, if present.
[25]:
#from pathlib import Path
#datafile = "file.h5"
#print(datafile)
#sp.calibrate_delay_axis(datafile=datafile)
delay_range = (-500, 1500)
sp.calibrate_delay_axis(delay_range=delay_range, preview=True)
Adding delay column to dataframe:
Append delay axis using delay_range = [-500, 1500] and adc_range = [475.0, 6400.0]
X Y t ADC Xm \
0 0.019212 0.019212 0.019212 0.019212 -13.117474
1 364.536080 1001.536080 70100.536080 6316.536080 355.044987
2 761.245431 818.245431 75615.245431 6316.245431 791.668430
3 691.838427 970.838427 66454.838427 6316.838427 713.394637
4 670.744246 711.744246 73025.744246 6316.744246 696.698186
5 299.415090 1164.415090 68459.415090 6316.415090 282.689663
6 571.180508 665.180508 73903.180508 6316.180508 590.187362
7 821.634527 544.634527 72631.634527 6317.634527 847.681856
8 817.584037 415.584037 72421.584037 6316.584037 838.058159
9 1006.088902 667.088902 72802.088902 6317.088902 1040.118473
Ym kx ky tm energy delay
0 87.347716 -2.095257 -1.825771 -48.190506 -25.209561 -660.331068
1 1031.806174 -1.107704 0.707629 70083.519298 -9.299837 1471.826525
2 839.832104 0.063488 0.192681 75614.359026 -16.703117 1471.728416
3 984.866899 -0.146473 0.581720 66449.160859 -0.818435 1471.928583
4 741.140573 -0.191259 -0.072047 73025.353135 -13.802416 1471.896792
5 1185.601674 -1.301789 1.120168 68432.901521 -5.958760 1471.785684
6 701.433799 -0.476962 -0.178556 73900.274450 -14.873737 1471.706501
7 586.542093 0.213737 -0.486740 72627.475101 -13.279788 1472.197309
8 466.185678 0.187923 -0.809582 72411.914464 -12.986686 1471.842713
9 709.296284 0.729926 -0.157466 72794.603766 -13.502166 1472.013132
5. Visualization of calibrated histograms#
With all calibrated axes present in the dataframe, we can visualize the corresponding histograms, and determine the respective binning ranges
[26]:
axes = ['kx', 'ky', 'energy', 'delay']
ranges = [[-3, 3], [-3, 3], [-6, 2], [-600, 1600]]
sp.view_event_histogram(dfpid=1, axes=axes, ranges=ranges)
Define the binning ranges and compute calibrated data volume#
[27]:
axes = ['kx', 'ky', 'energy', 'delay']
bins = [100, 100, 200, 50]
ranges = [[-2, 2], [-2, 2], [-4, 2], [-600, 1600]]
res = sp.compute(bins=bins, axes=axes, ranges=ranges, normalize_to_acquisition_time="delay")
Calculate normalization histogram for axis 'delay'...
Some visualization:#
[28]:
fig, axs = plt.subplots(4, 1, figsize=(6, 18), constrained_layout=True)
res.loc[{'energy':slice(-.1, 0)}].sum(axis=(2,3)).T.plot(ax=axs[0])
res.loc[{'kx':slice(-.8, -.5)}].sum(axis=(0,3)).T.plot(ax=axs[1])
res.loc[{'ky':slice(-.2, .2)}].sum(axis=(1,3)).T.plot(ax=axs[2])
res.loc[{'kx':slice(-.8, -.5), 'energy':slice(.5, 2)}].sum(axis=(0,1)).plot(ax=axs[3])
[28]:
<matplotlib.collections.QuadMesh at 0x7fab299c5670>
[29]:
fig, ax = plt.subplots(1,1)
(sp._normalization_histogram*90000).plot(ax=ax)
sp._binned.sum(axis=(0,1,2)).plot(ax=ax)
plt.show()
[ ]: